FIELD OF THE INVENTIONThe invention concerns a beam current limiting arrangement for a television receiver or monitor with provisions for displaying a small or auxiliary picture within a big or main picture within the same image, e.g., in a so-called picture-in-picture configuration.
BACKGROUND OF THE INVENTIONSome television receivers and monitors have so-called "picture-in-picture" (PIP) provisions for displaying a small picture corresponding to a video signal provided by an auxiliary video signal source within a large or main picture corresponding to a video signal provided by a main signal source. In a television receiver, the main video signal source may be the primary tuner of the television receiver and the auxiliary video signal source may be a second tuner included within the television receiver itself or within an external VCR coupled to the television receiver, or some other composite video signal source such as a VCR.
Television receivers and monitors usually include a beam current limiting (BCL) arrangement which controls contrast and/or the brightness characteristics of the video signals coupled to the picture tube in order to limit the beam current drawn by the picture tube. Beam current limiting is also referred to in the art as automatic beam limiting (ABL). The purpose of a BCL arrangement is to ensure that excessive beam currents, which may cause so-called "white spot blooming" and which may also cause damage to the picture tube, are not produced. A BCL arrangement senses the average current drawn by the picture tube from the high voltage transformer which supplies high operating voltages to the picture tube. Usually, the BCL arrangement generates a control signal for reducing the gain of the video signal processing channel to thereby reduce the peak-to-peak amplitude of the video signals coupled to the picture tube when the level of the beam current exceeds a predetermined threshold. The peak-to-peak amplitude of the video signals is related to the contrast of the reproduced image. The BCL arrangement may also generate a control signal for reducing the DC levels of the video signals coupled to the picture tube and thereby the brightness of the reproduced image.
A copending patent application Ser. No. 695,809, entitled TELEVISION RECEIVER WITH PICTURE IN PICTURE AND NON-LINEAR PROCESSING, filed on May 6, 1991 for R. L. Lineberry concerns a television system with both picture-in-picture and so called non-linear "black stretch" signal processing provisions. A non-linear "black-stretch" signal processing section operates to control the amplitudes of relatively low level video signals between black and a grey level in response to the average video signal level (sometimes referred to as the average picture level or simply as APL). More specifically, the amplitudes of low level video signals are increased for relatively dark scenes (i.e., scenes having low APL) and are relatively decreased for brighter scenes (i.e., scenes having higher APL). In the receiver described in the Lineberry patent application, the non-linear "black-stretch" signal processing operation is disabled during the PIP mode of operation while the small picture is being displayed. As a result, image details of dark scenes of the small picture will not be lost because of the reduction of the amplitudes of low level video signals by the "black-stretch" section in response to a high APL of bright scenes of the big picture.
SUMMARY OF THE INVENTIONAn aspect of the invention concerns the recognition that while BCL arrangements are usually thought to operate to inhibit excessive beam currents and are therefore normally inoperative, the operation of a BCL arrangement may adversely affect the visibility of the small picture produced by a television receiver or monitor with PIP provisions. For example, in large screen television receivers and monitors, the nominal gain of a video channel may be set to a relatively high level in order to maintain a relatively high average image brightness. In such situations, the BCL arrangement will be operative during a significant amount of time even with "normal" video signals and will reduce the contrast of a small picture which is inserted within a big picture during PIP mode of operation will be reduced to the same degree as that of the big picture. Moreover, while a non-linear "black-stretch" signal processing section, with which the Lineberry application is concerned, affects mid-range to low level portions of video signals, BCL contrast reduction affects the entire amplitude range of the video signals. Thus, the operation of the BCL arrangement tends to reduce the visibility of the small picture. Accordingly, another aspect of the invention concerns the recognition of the desirability of modifying the operation of the BCL arrangement during the time interval in which the small picture is being displayed to avoid unnecessary degradation of the small picture. This is made possible because the contribution of the small picture to the average beam current is small considering the relative sizes of the main and small pictures.
Still another aspect of the invention concerns a particular arrangement of apparatus for modifying the operation of the BCL arrangement during the time interval in which the small picture is being displayed.
A further aspect of the invention concerns the recognition that the manner in which the operation of the BCL arrangement is modified while the small picture is being displayed should not substantially affect the operation of the BCL arrangement for the big picture is being displayed. A still further aspect of the invention concerns a particular arrangement for accomplishing the latter.
BRIEF DESCRIPTION OF THE DRAWINGThe above referred to and other aspects of the invention will be described with reference to a preferred embodiment of the invention shown in the accompanying Drawing in which:
FIG. 1 is a schematic diagram, partially in block form, of a television receiver including a PIP system and a BCL arrangement constructed in accordance with the invention;
FIG. 1a is a block diagram of an implementation of a PIP system which may be employed in the television receiver shown in FIG. 1; and
FIG. 2 is a schematic diagram, partially in block form, of the television receiver shown in FIG. 1, modified in accordance with another aspect of the invention.
In FIGS. 1 and 2, the same or similar elements are identified by the same reference numbers.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTThe PIP television receiver shown in FIG. 1 includes a "main" video signal input section 1 which provides a "main" composite video (MCV) signal including luminance, synchronization and modulated chrominance components and an auxiliary videosignal input section 3 which provides an auxiliary composite video (ACV) signal. Either one or both of main auxiliaryvideo input sections 1 and 3 may comprise a tuner, IF and demodulator section for deriving a baseband composite video signal from a received RF television signal or simply a baseband composite video signal input section to which a video cassette recorder, video disc player or other video signal source may be connected. The MCV and ACV signals are coupled to aPIP processing section 5.PIP processing section 5 produces a combined baseband luminance signal (Y) and a combined modulated chrominance signal (C) at respective outputs. In a PIP mode of operation, the combined Y and C signals represent a main or a big picture and auxiliary or small picture inserted within the main picture. A PIP mode of operation is selected in response to a control signal generated by a receiver control unit 7 in response to a user initiated command entered via a remote control unit (not shown). The MCV or ACV may be selectively exchanged to serve as the signals from which the main and small pictures are derived. In a normal or non-PIP mode of operation, the auxiliary or small picture is eliminated and only the main or big picture is displayed.
A block diagram of an implementation ofPIP processor 5 is shown in FIG. 1a. As shown in FIG. 1a,PIP processor 5 includes an input switch 5-1 which selects one of the MCV or ACT signals coupled to its inputs for the big picture and the other signal for the small picture. Switch 5-1 is controlled by a control unit 5-3 which receives digital PIP control words, in serial format, from receiver control unit 7 (shown in FIG. 1). The digital control words also control the location and size of the small picture.
A Y/C separator 5-5 having an input coupled to one output of input switch 5-1 provides separated luminance (YB) and chrominance (CB) signal components corresponding to the big picture and a Y/C separator 5-7 coupled to the other output of input switch 5-1 provides separated (YS) and chrominance (CS) signal components corresponding to the small picture. The YB and CB output signals of Y/C separator 5-1 are coupled to respective inputs of an output switch 5-7.
The YS output signal of Y/C separator 5-7 is coupled directly to a digital picture compressor 5-11. The CS output signal of Y/C separator 5-7 is demodulated in a color demodulator 5-13 to produce color difference (US and VS) signals. The US and VS signals are also coupled to digital picture compressor 5-11. Picture compressor 5-11 includes a memory and compresses each of signal components it receives in the vertical direction by deleting lines and in the horizontal direction by deleting pixels to form a compressed luminance component (CSY) and two compressed color difference signals (CUS and CVS) corresponding to the small picture. The compressed signals are stored in the memory of digital compressor 5-1 and "read-out" of the memory in synchronism with horizontal-rate and vertical-rate sync pulses generated by deflection units of the receiver (shown in FIG. 1) at the appropriate time under the control of PIP control unit 5-3 in order to properly position the small picture relative to the big picture. A color modulator 5-15 modulates the compressed color difference signals (CUS and CVS) onto a color subcarrier to form the chrominance signal (CCS) for the small picture.
The CYS and CCS signals are coupled to respective inputs of output switch 5-9. PIP control unit 5-3 generates a "fast" (video rate) switching (FS) signal which controls switch 5-9 so that small picture video signals CYS and CCS are substituted for the big picture video signals YB and CB at the proper time to form the combined Y and C output signals ofPIP processor 5.
Returning to FIG. 1, the luminance output signal (Y) ofPIP processor 5 is coupled to a luminance signal processing unit which performs signal processing operations such as peaking and non-linear "black-stretch" control. The output signal of luminancesignal processing unit 9 is coupled to amatrix 10. The chrominance signal output signal (C) ofPIP processor 5 is coupled to a chrominancesignal processing unit 11 which performs signal processing operations such as color demodulation, and color saturation and tint and produces green and blue color difference (r-Y, the g-Y and b-Y) signals. The r-Y, g-Y and b-Y signals are coupled tomatrix 10.Matrix 10 combines the Y signal with the r-Y, g-Y and b-Y signals to produce low level red, green and blue color (r, g, b) signals.
The r, g and b signals are applied torespective contrast sections 13r, 13g and 13b. The output signals ofcontrast sections 13r, 13g and 13b are coupled torespective brightness sections 15r, 15g and 15b. The output signals ofbrightness sections 15r, 15g and 15b are coupled to respectivepicture tube drivers 17r, 17g and 17b which produce high level red, green and blue drive (R, G, and B) signals. The R, G and B signals are coupled to respective electron guns of apicture tube 19. Contrastsections 13r, 13g and 13b control the peak-to-peak amplitude of the R, G and B signals coupled topicture tube 19.Brightness sections 15r, 15g and 15b control the DC level of the R, G and B signals.
The Y output ofPIP processor 5 is also coupled to a synchronization ("sync") separator which derives horizontal and vertical sync signals. The horizontal sync signal is coupled to ahorizontal deflection section 23 which supplies horizontal deflection signals to deflection coils 25 associated with thepicture tube 19. The vertical sync signal is coupled to avertical deflection section 27 which supplies vertical deflection signals to deflection coils 25. The horizontal deflection signals are also coupled to ahigh voltage section 29 which supplies high operating voltages topicture tube 19.
While various ones of the sections described above are shown separately, they may be incorporated in one or more integrated circuits (ICs). For example, luminancesignal processing section 9, chrominancesignal processing section 11,sync separator 21 and portions ofdeflection sections 23 and 27 may comprise respective sections of a TA8680 IC available from Toshiba Corporation.Matrix 9,contrast sections 13r, 13g and 13b, andbrightness sections 15r, 15g and 15b may comprise respective sections of a TA7730 IC also available from Toshiba Corporation.
In addition toPIP processing section 5, receiver control unit 7 controls various other sections of the television receiver such ascontrast sections 13r, 13g and 13b andbrightness sections 15r, 15g and 15b in response command signals initiated by a user via a remote control unit (not shown). Control unit 7 includes a microprocessor operating under the control of a stored program. Forcontrast sections 13r, 13g and 13b andbrightness sections 15r, 15g and 15b control unit 7 generates respective pulse signals encoded in binary rate or pulse width format in accordance with the user's performances. The pulse signals are filtered to produce respective analog contrast and brightness control signals.
The contrast control pulse signal is coupled via an emitter-follower configuredNPN transistor 31 to alow pass filter 33 including a series-connectedresistor 35 and a shunt-connectedcapacitor 37. The contrast control analog signal is developed acrosscapacitor 37 and coupled to respective contrast control inputs ofcontrast sections 13r, 13g and 13b through a switching arrangement provided in accordance with an aspect of the present invention, as will be described in detail below. The brightness control analog signal forbrightness sections 15r, 15g and 15b is generated in a similar manner by an arrangement including a low-pass filter arrangement 39 in response to a brightness control pulse signal generated by control unit 7.
As earlier noted, it is desirable to limit the electron beam current in order to prevent "white spot blooming". To this end, in the television receiver shown in FIG. 1, a beam current limiting (BCL)section 41 monitors the average current drawn by the picture tube from highvoltage power supply 29 and, in response, generates control signals for reducing the contrast and brightness of the reproduced images when the beam current exceeds a predetermined threshold. U.S. Pat. No. 4,167,025 entitled AUTOMATIC PEAK BEAM CURRENT LIMITER by D. H. Willis, issued on Sep. 4, 1979 discloses a suitable arrangement forBCL section 41. It is desirable to reduce the contrast of the image before reducing the brightness of the image because contrast changes are subjectively less noticeable to viewers than brightness changes. This sequential operation is established by threshold devices associated withBCL unit 41 which are represented in FIG. 1 bydiodes 43 and 45. The BCL contrast and brightness control signals generated byBCL section 41 are coupled to respective ones of contrastcontrol voltage filter 33 and brightnesscontrol voltage filter 39. In the exemplary embodiment, BCL brightness reduction is considered an "emergency" measure and therefore rarely occurs except when the beam current is exceptionally high.
In addition to the average beam current responsive beam current limiting provided byBCL section 41, the peak drive level is limited to a predetermined value since electron beam spot size expands non-linearly at higher beam current amplitudes. This is accomplished by sensing the peak of a signal representative of the luminance component of the image produced bypicture tube 19. Specifically, a combiningcircuit 47 combines (e.g., adds) the processed r, g and b color signals produced bybrightness sections 15r, 15g and 15b to produce a signal representative of the luminance component of the displayed image. The output signal of combiningcircuit 47 is coupled to apeak detector 49 which detects the peak of the white-going portion of the luminance representative signal provided by the combiningcircuit 47. The white-peak representative output signal ofpeak detector 49 is coupled to athreshold comparator 50 which generates a control signal for reducing the contrast of the reproduced image when the detected white-peak exceeds a predetermined threshold. The contrast control signal produced bycomparator 50 is coupled by an emitter-follower configuredPNP transistor 51 to filtercapacitor 37 of contrastcontrol voltage filter 33 where it is filtered and combined with the user responsive and BCL contrast control signals to form a combined contrast control signal. The combined contrast control signal is coupled to respective contrast control inputs ofcontrast sections 13r, 13g and 13b. The white-peak responding arrangement operates to reduce the amplitudes of the r, g and b signals when their combination corresponds to an excessively peak white image. Such automatic contrast control (which also may be called "auto-pix", "pix" being an abbreviation for "picture") prevents loss of detail sharpness in highlight (white) areas due to blooming, while permitting high contrast (and therefore subjectively bright) images when the signal peaks remain below the blooming threshold.
The television receiver described so far with respect to FIG. 1 may be constructed in a manner similar to RCA brand name television receivers employing CTC-169 electronic chassis described in the publications entitled "RCA/GE Color Television Basic Service Data CTC 169 (DV)" and "The CTC 168/169 Technical Training Manual", both published in 1990 by Thomson Consumer Electronics, Inc., Indianapolis, Ind.
In the television shown in FIG. 1, the nominal gain of the video channels which produce the R, G and B signals coupled topicture tube 19 is set relatively high in order to produce high contrast images and therefore subjectively bright images. As earlier noted, under suchconditions BCL section 41 will operate to reduce image contrast during a significant amount of time during the reception of normal program material. This operation may be detrimental to the visibility of he small picture because the small picture undergoes the same contrast reduction as the big picture. The detrimental effect of contrast BCL operation occurs independently of whether the average picture level of the small picture is low or high because the small picture contributes very little to the average beam current due to the relatively small area of the small picture compared to the big picture. The remaining portion of the television receiver shown in FIG. 1 concerns an arrangement constructed in accordance with an aspect of the invention for inhibiting BCL contrast reduction during the time that the small picture is being displayed.
The arrangement for inhibiting BCL contrast reduction during the time interval in which the small picture is being displayed includes aswitching section 53 coupled between the contrast control output (diode 43) ofBCL section 41 and the contrast control inputs ofcontrast sections 14r, 13g and 13b.Switching section 53 comprises adiode 55 connected in series betweenfilter capacitor 37 of contrastcontrol voltage filter 33 and the contrast control inputs ofcontrast sections 13r, 13g and 13b, and aresistor 57 anddiodes 59 and 61 connected in series between the "fast" switching (FS) signaloutput PIP processor 5 and the cathode ofdiode 55. The arrangement also includes a second or auxiliarylow pass filter 63, including a series-connectedresistor 65 and a shunt-connectedcapacitor 67, coupled to the output (emitter electrode) of emitter-follower configuredNPN transistor 31. The output signal of auxiliarycontrast control filter 63 developed acrossfilter capacitor 67 is coupled to the junction ofresistor 57 and the anode ofdiode 59 via an emitter-follower configuredPNP transistor 69. Emitter-follower configuredPNP transistor 69, which utilizesresistor 57 as its load resistor, also comprises a part of switchingsection 53. Second orauxiliary filter 63 develops a second or auxiliary analog contrast control voltage representative of the user's contrast control preference. The auxiliary contrast control voltage has substantially the same level as that portion of the first or main contrast control voltage developed acrosscapacitor 37 which represents the user's contrast control preference (without contribution fromBCL section 41 and white-peak detector 49).
In operation, while the big picture is being displayed,diode 55 is forward biased and therefor conductive, anddiodes 59 and 61 andtransistor 69 are reverse biased and therefore non-conductive by virtue of the relatively low level (e.g., approximately 0 volts) of the FS signal and the relatively high level of main control voltage developed acrosscapacitor 37. As a result, the main control voltage, which corresponds to the combination of the user responsive contrast control signal, the BCL control signal and the automatic contrast control signal, is coupled to the control inputs ofcontrast sections 13r, 13g and 13b. However, while the small picture is being displayed, the level of the FS signal is a relatively high (e.g., +12 volts). This causesdiodes 59 and 61 andtransistor 69 to be forward biased and therefore rendered conductive anddiode 55 to be reverse-biased and therefore rendered non-conductive. As a result, the main control signal, including the BCL and automatic contrast control contributions, is decoupled from the control inputs ofcontrast sections 13r, 13g and 13b and the auxiliary control signal, representing only the user's contrast control preference, is coupled to the control inputs ofcontrast control sections 13r, 13g and 13b instead. The voltage drop acrossdiode 59, which is poled in opposition to the base-emitter junction ofPNP transistor 69, compensates for the voltage drop across the base-emitter junction oftransistor 69. The voltage drop acrossdiode 61 substantially matches the voltage drop acrossdiode 55 and therefore aids in equalizing the auxiliary contrast control voltage with that portion of the main contrast control voltage which represents the user's contrast control preference. In this manner, BCL contrast reduction which might otherwise reduce the visibility of the small picture is avoided.
It is noted that while the BCL operation is disabled during the time interval in which the small picture is being displayed, the main control voltage developed acrossfilter capacitor 37 of mainlow pass filter 33 continues to be responsive to the average beam current drawn bypicture tube 19 throughout the entire image interval, including the time interval in which the small picture is being displayed. Accordingly, the BCL control signal for the big picture is not disturbed and continues to represent the beam current drawn for the entire image.
In the arrangement shown in FIG. 1, both the BCL and automatic contrast reduction operations are disabled while the small picture is being displayed. However, it may be desirable to provide for some beam current limiting action in response to excessive peak-white video signals because the beam current increases nonlinearly in response to high level video signals. Accordingly, the arrangement shown in FIG. 2 includes provisions for maintaining the peak-white automatic contrast control reduction operation while the small picture is being displayed. Specifically, an additional emitter-follower configuredPNP transistor 71 is coupled between the output ofcomparator 50 and the junction ofresistor 65 andcapacitor 67 of auxiliarylow pass filter 63. As a result, the automatic contrast control voltage generated bywhite peak detector 49 will be coupled to the control inputs ofcontrast sections 13r, 13g and 13b, together with the auxiliary control voltage representative of the user's contrast control preference, while the small picture is being displayed.
In summary, an arrangement has been described for modifying the operation of apparatus for limiting the beam current drawn by a picture tube of a television system including PIP provisions during the time interval in which the small picture is being displayed so that the visibility of the small picture does not suffer. In the preferred embodiment which has been described, one or both of the beam current responsive and video signal responsive automatic contrast control sections are disabled and a fixed control signal, preferably corresponding to the user's contrast control preference, is substituted for the variable control signal generated by the beam current limiting section.
It will be appreciated by those skilled in the art that other related measures for improving the visibility of the small picture may additionally or alternatively be employed. For example, the contrast may actually be increased during the time period in which the small picture is being displayed. In addition, in the described television system, the disabling arrangement is only associated with the contrast control section of the receiver because it is assumed that brightness beam limiting rarely occurs except at exceptionally high beam currents. However, in other television system in which brightness beam current limiting may occur more frequently, it may be desirable to employ an arrangement similar to the one described with respect to the contrast BCL section for disabling the brightness BCL section. Further, while an auxiliary or second filter is provided for generating an auxiliary contrast control signal which is substituted for the main control signal, it is possible to dispense with such an auxiliary filter in configurations in which the contrast control pulse signal and BCL contrast control signal are not filtered by the same filter capacitor but are rather filtered by separate filter capacitors and the resulting filtered control signals are combined. In that case, it is necessary only to decouple the BCL contrast control signal filter from the combining section while the small picture is being displayed. Still further, while the disabling arrangement has been described with respect to a PIP system in which a small picture is inserted within a bigger picture the disabling arrangement is also applicable to a system in which a small picture is located in other positions with respect to a large picture, such as adjacent to a big picture in a so called POP (picture outside of picture) configuration. Additionally, while the present invention has been described in terms of direct view type of television, the invention could also be used in a projection type of television system employing separate picture tubes for red, green and blue images. The use of the invention in projection television systems is particularly advantageous since projection tend to be operated with exceptional high video channel gains to maintain a relatively high average picture brightness. This tends to cause the BCL arrangement to be operative during even more significant amounts of time. It is further noted that the present invention may also be employed in a television monitor system which does not include a tuner. These and other modifications are considered to be within the scope of the present invention defined by the following claims.